Patient characteristics influencing the variability of distributed parameter-based models in DCE-CT kinetic analysis.

Kinetic parameter variability may be sensitive to kinetic model choice, kinetic model implementation or patient-specific effects. The purpose of this study was to assess their impact on the variability of dynamic contrast-enhanced computed tomography (DCE-CT) kinetic parameters. A total of 11 canine patients with sinonasal tumours received high signal-to-noise ratio, test-double retest DCE-CT scans. The variability for three distributed parameter (DP)-based models was assessed by analysis of variance. Mixed-effects modelling evaluated patient-specific effects. Inter-model variability (CVinter ) was comparable to or lower than intra-model variability (CVintra ) for blood flow (CVinter :[4-28%], CVintra :[28-31%]), fractional vascular volume (CVinter :[3-17%], CVintra :[16-19%]) and permeability-surface area product (CVinter :[5-12%], CVintra :[14-15%]). The kinetic models were significantly (P<0.05) impacted by patient characteristics for patient size, area underneath the curve of the artery and of the tumour. In conclusion, DP-based models demonstrated good agreement with similar differences between models and scans. However, high variability in the kinetic parameters and their sensitivity to patient size may limit certain quantitative applications.

PspK of Streptococcus pneumoniae increases adherence to epithelial cells and enhances nasopharyngeal colonization.

Streptococcus pneumoniae (the pneumococcus) colonizes the human nasopharynx and can cause invasive disease aided by the pneumococcal capsule. Group II nontypeable S. pneumoniae (NTSp) lacks a polysaccharide capsule, and a subgroup of NTSp carriage isolates has been found to have a novel gene, pneumococcal surface protein K (pspK), which replaces the capsule locus. A recent rise in the number of NTSp isolates colonizing the human nasopharynx has been observed, but the colonization factors of NTSp have not been well studied. PspK has been shown to play a role in mouse colonization. We therefore examined PspK-mediated immune evasion along with adherence to host cells and colonization. PspK bound human secretory immunoglobulin A (sIgA) but not the complement regulator factor H and did not decrease C3b deposition on the pneumococcal surface. PspK increased binding of pneumococci to epithelial cells and enhanced pneumococcal colonization independently of the genetic background. Understanding how NTSp colonizes and survives within the nasopharynx is important due to the increase in NTSp carriage. Our data suggest that PspK may aid in the persistence of NTSp within the nasopharynx but is not involved in invasion.

Combined analysis of cytokine genotype polymorphism and the level of expression with allograft function in African-American renal transplant patients.

Cytokine gene polymorphism and expression levels were evaluated in a group of African-American patients who had undergone renal transplantation. It was hypothesized that possession of specific cytokine alleles might be influential in predisposing the recipient to allograft rejection. Thus, we sought to establish a relationship between cytokine gene polymorphism, the levels of cytokine expression, and the outcome of allograft function. Cytokine genotypes and mRNA transcript levels of IL-2, TNF-alpha, TGF-beta1, IL-10, IL-6 and IFN-gamma were determined using peripheral blood cells. Genomic DNA samples from 77 transplant recipients and 77 controls were tested by a multiplex PCR with specific primers for the above cytokines. The frequency distributions of cytokines were analyzed in respect to the clinical characterization, including delayed graft function (DGF), rejection episodes (REs) and stable graft function (SGF). The mRNA transcript level was tested both at pre- and early post-transplantation (day 1 and day 4) with primers for coding regions of the above cytokines in a RT-PCR assay. The majority of recipients with successful graft function were matched with their donors for only three out of the six HLA alleles. We have shown that the TGF-beta1 T/C G/G high producer and IFN-gamma T/A intermediate producer genotypes were associated with allograft rejection, whereas low IFN-gamma producer and high IL-10 producer genotypes were significantly protective of the allograft. There was some correlation between the TGF-beta1 high producer genotype and DGF, but it was not statistically significant. Overall, 77% of those who experienced REs carried the TGF-beta1 T/C G/G, high producer genotype as compared with 52% who experienced DGF, 39% with SGF (P<0.01, RR=2.0), and 27.3% of controls (P<0.003, RR=2.6). The IFN-gamma T/A intermediate producer genotype was found in 69.2% of patients with REs as compared with 26.8% of patients with SGF (P<0.008, RR=2.85). The IL-10, ATA/ATA low producer genotype was found in 38.5% of recipients with REs and 14.6% of recipients without REs (P<0.04, RR=0.53). Expression levels of mRNA transcript were correlated with genotype data, except for the TGF-beta1 high producer genotype where there was no significant difference between the level of mRNA transcript at pre- and post-transplantation. Low DRbeta1 and high DPbeta1 expression by recipient peripheral blood mononuclear cells before transplantation was associated with more SGF, whereas high DRbeta1 and low DPbeta1 expression at pretransplantation was associated with more REs (DRbeta1, P<0.001 and DPbeta1, P<0.05, respectively). We concluded that, dual analysis of cytokine genotype and expression levels by peripheral cells may be an important clue to understanding the contribution of the recipient's immune response to an allograft pre- and post-transplantation. Identification of peripheral markers diagnostic of rejection could allow advance anticipation of clinical outcome, and might reduce the need for tissue biopsy.

Genetic immunization with the region encoding the alpha-helical domain of PspA elicits protective immunity against Streptococcus pneumoniae.

Pneumococcal surface protein A (PspA) is a pneumococcal virulence factor capable of eliciting protection against pneumococcal infection in mice. Previous studies have demonstrated that the protection is antibody mediated. Here we examined the ability of pspA to elicit a protective immune response following genetic immunization of mice. Mice were immunized by intramuscular injections with a eukaryotic expression vector encoding the alpha-helical domain of PspA/Rx1. Immunization induced a PspA-specific serum antibody response, and immunized mice survived pneumococcal challenge. Survival and antibody responses occurred in a dose-dependent manner, the highest survival rates being seen with doses of 10 microg or greater. The ability of genetic immunization to elicit cross-protection was demonstrated by the survival of immunized mice challenged with pneumococcal strains differing in capsule and PspA types. Also, immunized mice were protected from intravenous and intratracheal challenges with pneumococci. Similar to the results seen with immunization with PspA, the survival of mice genetically immunized with pspA was antibody mediated. There was no decline in the level of protection 7 months after immunization. These results support the use of genetic immunization to elicit protective immune responses against extracellular pathogens.

Characterization of binding of human lactoferrin to pneumococcal surface protein A.

Human lactoferrin is an iron-binding glycoprotein that is particularly prominent in exocrine secretions and leukocytes and is also found in serum, especially during inflammation. It is able to sequester iron from microbes and has immunomodulatory functions, including inhibition of both complement activation and cytokine production. This study used mutants lacking pneumococcal surface protein A (PspA) and PspC to demonstrate that the binding of human lactoferrin to the surface of Streptococcus pneumoniae was entirely dependent on PspA. Lactoferrin bound both family 1 and family 2 PspAs. Binding of lactoferrin to PspA was shown by surface colocalization with PspA and was verified by the lack of binding to PspA-negative mutants. Lactoferrin was expressed on the body of the cells but was largely absent from the poles. PspC showed exactly the same distribution on the pneumococcal surface as PspA but did not bind lactoferrin. PspA's binding site for lactoferrin was mapped using recombinant fragments of PspA of families 1 and 2. Binding of human lactoferrin was detected primarily in the C-terminal half of the alpha-helical domain of PspA (amino acids 167 to 288 of PspA/Rx1), with no binding to the N-terminal 115 amino acids in either strain. The interaction was highly specific. As observed previously, bovine lactoferrin bound poorly to PspA. Human transferrin did not bind PspA at all. The binding of lactoferrin to S. pneumoniae might provide a way for the bacteria to interfere with host immune functions or to aid in the acquisition of iron at the site of infection.

PspC, a pneumococcal surface protein, binds human factor H.

PspC was found to bind human complement factor H (FH) by Western blot analysis of D39 (pspC(+)) and an isogenic mutant TRE108 (pspC). We confirmed that PspA does not bind FH, while purified PspC binds FH very strongly. The binding of FH to exponentially growing pneumococci varied among different isolates when analyzed by fluorescence activated cell sorting analysis.

A new HLA-DPA1 allele, DPA1*02016, identified in African-American population.

A new HLA-DPA1 allele has been found in the African-American population. This newly discovered type is homologous with the DPA1*02011 allele, except in codon 38 of the DPA1 sequence. The variant of DPA1 was detected by sequence-specific oligonucleotide (SSO) typing, and specified by cloning and sequencing methods. GenBank accession number is AF165160. The WHO Nomenclature Committee has officially assigned the name DPA1*02016.

In vitro activity of four fluoroquinolones against clinical isolates of Pseudomonas aeruginosa determined by the E test.

Ciprofloxacin, levofloxacin, ofloxacin, and trovafloxacin were tested by the E-test against 100 clinical isolates of Pseudomonas aeruginosa. Ciprofloxacin was the most active of the tested agents with 82% of isolates having a MIC 8). Levofloxacin and trovafloxacin had nearly identical potency: 75% and 76% of the isolates were inhibited by 8 for levofloxacin; 0.19->8 for trovafloxacin). Ofloxacin was the least active of the four quinolones, with 43% of the isolates having a MIC >2 mg/l. All isolates resistant to ciprofloxacin were also resistant to the other agents, i.e. resistance to ciprofloxacin predicted resistance to all the quinolones tested in every case. This data demonstrates that fluoroquinolones are active agents against P. aeruginosa. In vitro susceptibility testing, however, is crucial to assess the resistance pattern in any specific location and for each individual agent.

Pneumococcal diversity: considerations for new vaccine strategies with emphasis on pneumococcal surface protein A (PspA).

Streptococcus pneumoniae is a problematic infectious agent, whose seriousness to human health has been underscored by the recent rise in the frequency of isolation of multidrug-resistant strains. Pneumococcal pneumonia in the elderly is common and often fatal. Young children in the developing world are at significant risk for fatal pneumococcal respiratory disease, while in the developed world otitis media in children results in substantial economic costs. Immunocompromised patients are extremely susceptible to pneumococcal infection. With 90 different capsular types thus far described, the diversity of pneumococci contributes to the challenges of preventing and treating S. pneumoniae infections. The current capsular polysaccharide vaccine is not recommended for use in children younger than 2 years and is not fully effective in the elderly. Therefore, innovative vaccine strategies to protect against this agent are needed. Given the immunogenic nature of S. pneumoniae proteins, these molecules are being investigated as potential vaccine candidates. Pneumococcal surface protein A (PspA) has been evaluated for its ability to elicit protection against S. pneumoniae infection in mouse models of systemic and local disease. This review focuses on immune system responsiveness to PspA and the ability of PspA to elicit cross-protection against heterologous strains. These parameters will be critical to the design of broadly protective pneumococcal vaccines.

Comparison of the PspA sequence from Streptococcus pneumoniae EF5668 to the previously identified PspA sequence from strain Rx1 and ability of PspA from EF5668 to elicit protection against pneumococci of different capsular types.

PspA (pneumococcal surface protein A) is a serologically varied virulence factor of Streptococcus pneumoniae. In mice, PspA has been shown to elicit an antibody response that protects against fatal challenge with encapsulated S. pneumoniae, and the protection-eliciting residues have been mapped to the alpha-helical N-terminal half of the protein. To date, a published DNA sequence for pspA is available only for S. pneumoniae Rx1, a laboratory strain. PspA/EF5668 (EF5668 indicates the strain of origin of the PspA) is serologically distinct from PspA/Rx1. Sequencing of the gene encoding PspA/EF5668 revealed 71% identity with that of PspA/Rx1. The greatest amount of divergence between the two proteins was seen in their alpha-helical portions, which are surface exposed and probably under selective pressure to diversify serologically. In spite of the diversity within the alpha-helical regions of PspAs, we have observed that recombinant PspA (rPspA)/EF5668, like rPspA/Rx1, can elicit cross-protection against pneumococci of different capsular and PspA serological types.

A live recombinant avirulent oral Salmonella vaccine expressing pneumococcal surface protein A induces protective responses against Streptococcus pneumoniae.

A live oral recombinant Salmonella vaccine strain expressing pneumococcal surface protein A (PspA) was developed. The strain was attenuated with Deltacya Deltacrp mutations. Stable expression of PspA was achieved by the use of the balanced-lethal vector-host system, which employs an asd deletion in the host chromosome to impose an obligate requirement for diaminopimelic acid. The chromosomal Deltaasd mutation was complemented by a plasmid vector possessing the asd+ gene. A portion of the pspA gene from Streptococcus pneumoniae Rx1 was cloned onto a multicopy Asd+ vector. After oral immunization, the recombinant Salmonella-PspA vaccine strain colonized the Peyer's patches, spleens, and livers of BALB/cByJ and CBA/N mice and stimulated humoral and mucosal antibody responses. Oral immunization of outbred New Zealand White rabbits with the recombinant Salmonella strain induced significant anti-PspA immunoglobulin G titers in serum and vaginal secretions. Polyclonal sera from orally immunized mice detected PspA on the S. pneumoniae cell surface as revealed by immunofluorescence. Oral immunization of BALB/cJ mice with the PspA-producing Salmonella strain elicited antibody to PspA and resistance to challenge by the mouse-virulent human clinical isolate S. pneumoniae WU2. Immune sera from orally immunized mice conferred passive protection against otherwise lethal intraperitoneal or intravascular challenge with strain WU2.

Enhanced protective antibody responses to PspA after intranasal or subcutaneous injections of PspA genetically fused to granulocyte-macrophage colony-stimulating factor or interleukin-2.

Antibody to pneumococcal surface protein A (PspA) has been shown to be protective for Streptococcus pneumoniae infections in mice. In an attempt to define a model for inducing protective antibody to PspA in the absence of adjuvant, we designed two genetic fusions, PspA-interleukin-2 [IL-2]) and PspA-granulocyte-macrophage colony-stimulating factor (GM-CSF). These constructs maintained high cytokine function in vitro, as tested by their activity on IL-2 or GM-CSF-dependent cell lines. While intranasal immunization with PspA induced no detectable anti-PspA response, both PspA-IL-2 and PspA-GM-CSF stimulated high immunoglobulin G1 (IgG1) antibody responses. Interestingly, only the PspA-IL-2, not the PspA-GM-CSF, construct stimulated IgG2a antibody responses, suggesting that this construct directed the response along a TH1-dependent pathway. Comparable enhancement of the anti-PspA response with similar isotype profiles was observed after subcutaneous immunization as well. The enhancement observed with PspA-IL-2 was dependent on IL-2 activity in that it was not seen in IL-2 receptor knockout mice, while PspA in alum induced high-titer antibody in these mice. The antibody was tested for its protective activity in a mouse lethality model using S. pneumoniae WU-R2. Passive transfer of 1:90 dilutions of sera from mice immunized with PspA-IL-2 and PspA-GM-CSF elicited protection of CBA/N mice against intravenous challenge with over 170 50% lethal doses of capsular type 3 strain WU2. Only 0.17 microg or less of IgG antibody to PspA was able to provide passive protection against otherwise fatal challenge with S. pneumoniae. The data demonstrate that designing protein-cytokine fusions may be a useful approach for mucosal immunization and can induce high-titer systemic protective antibody responses.

Immunization with a plasmid expressing pneumococcal surface protein A (PspA) can elicit protection against fatal infection with Streptococcus pneumoniae.

Pneumococcal surface protein A (PspA) is a protectioneliciting protein of Streptococcus pneumoniae. We observed that immunization of BALB/c mice with a plasmid expressing PspA significantly protected the mice from lethal challenge with S. pneumoniae when compared to control mice that received injections of the plasmid vector alone. The plasmid construct expressing PspA has been designated pKSD2601. Mice immunized intramuscularly with pKSD2601 had a mean log of colony-forming units of 2.67 +/- 0.25 pneumococci circulating in their blood at 24 h after challenge as compared with control mice that had a mean log of colony-forming units of 4.95 +/- 0.59. Those mice with lower numbers of pneumococci subsequently survived the challenge. Given the quantitative nature and ultimate end point (ie live versus dead) our mouse model should be useful in working out optimum expression of bacterial genes for DNA immunization.

Oligonucleotides identify conserved and variable regions of pspA and pspA-like sequences of Streptococcus pneumoniae.

Pneumococcal surface protein A (PspA) is an immunogenic surface protein of Streptococcus pneumoniae. PspA of S. pneumoniae strain Rx1 is a 65-kDa protein composed of an alpha-helical N-terminus of 288 amino acids followed by an 82-amino-acid proline-rich region, 10 repeats of 20 amino acids each, and a 17-amino-acid C-terminus. It has been demonstrated that the 3'-half of pspA is relatively conserved among unrelated pneumococcal isolates and the 5'-half of the gene is highly variable. Additionally, nearly all pneumococcal strains contain at least one other locus with sequence homology to pspA. In this study oligonucleotides derived from the DNA sequence of pspA of Rx1 were used both as hybridization probes and as primers in the polymerase chain reaction (PCR) to investigate genetic variation within domains of pspA and in the pspA-like sequences from 18 strains representing 12 capsule and 9 PspA serotypes. Sequences encoding the leader peptide, the proline-rich region, and the repeat region are highly conserved among pspA and pspA-like sequences. The alpha-helical coding domain is highly diverse among pspA and pspA-like sequences of different strains.

Oral immunization with PspA elicits protective humoral immunity against Streptococcus pneumoniae infection.

Streptococcus pneumoniae is a major respiratory mucosal pathogen affecting infants and children. Although a polysaccharide-based vaccine has been useful in adult populations, it does not elicit protective immunity in infants and young children. Pneumococcal surface protein A (PspA) is a highly immunogenic surface protein produced by all strains of Streptococcus pneumoniae. Previous studies have shown that systemic immunization of mice with PspA can elicit protective immunity against fatal pneumococcal infection. In this study, we demonstrated that oral immunization with PspA could elicit protective immune responses against pneumococcal infection. When mice were orally immunized with PspA alone, low levels of PspA-specific immunoglobulin G (IgG) responses were induced in serum; none was induced in secretion. On the other hand, when PspA was given orally with the mucosal adjuvant cholera toxin (CT), significant levels of IgG and IgA anti-PspA responses were induced in serum. The major IgG subclass was IgG1, followed by IgG2b, a profile of antibody response supported by Th2-type cells. In addition, all mice orally immunized with PspA and CT were protected from the lethal challenge with capsular serotype 3 S. pneumoniae A66. These results suggested that an oral PspA vaccine may be a useful means of preventing pneumococcal disease.

DNA polymorphisms and variant penicillin-binding proteins as evidence that relatively penicillin-resistant pneumococci in western Canada are clonally related.

Previous studies have suggested that relatively penicillin-resistant (RPR) capsular group 9L strains in western Canada may be clonally related. To test this hypothesis, restriction fragment length polymorphisms (RFLPs) were examined using DNA probes for pspA and a newly recognized pneumococcal genetic element, IS1167. Penicillin-binding proteins (PBPs) and PBP genes from representative strains were also studied. All RPR type 9L strains demonstrated an identical RFLP when probed with IS1167, and 12 of 14 RPR strains had the same RFLP when examined with pspA. Amplification of pspA by polymerase chain reaction and restriction endonuclease digestion showed that the 9L strains had common DNA fragments not identified in any of the penicillin-susceptible strains. The 9L strains apparently have a low-affinity PBP 2B distinct from those of other capsular types. These data derived from new genetic markers and PBP analysis strongly support a clonal origin of RPR type 9L pneumococci of western Canada.

Evidence for the simultaneous expression of two PspAs by a clone of capsular serotype 6B Streptococcus pneumoniae.

Pneumococcal surface protein A (PspA) has been shown to be a serologically variable virulence factor of Streptococcus pneumoniae. In mice, PspA can elicit antibodies capable of protecting them against otherwise fatal infections with encapsulated pneumococci. In previous studies it has been reported that almost all isolates have two apparently unlinked genomic sequences that are highly homologous to the 5' and 3' halves of Rx1 pspA, although out MAbs to PspA have not detected more than one PspA in any given isolate of S. Pneumoniae. Recently, we have identified four isolates from a clone of capsular serotype 6B pneumococci (MC25-28) that simultaneously express two distinct PspAs. Each of the isolates (MC25-28) exhibited the same two Kpn I fragments (each containing a Hind III site) that hybridized with Rx1 pspA. MAbs specific for PspA detected two PspAs characterized by different molecular weights and different serologic patterns of reactivity (PspA type 6 detected by MAbs XiR278 and 2A4, and PspA type 34 detected only by MAb 7D2) in each of the four isolates. In previous studies XiR278 and 2A4 frequently have been observed to react with PspA epitopes of the same strain. Based on molecular weight data both epitopes were always present on the same molecule. Our present findings raise the possibility that pneumococci make a second serologically variable PspA which is generally not detected by currently available MAbs to PspA.

Systemic and mucosal protective immunity to pneumococcal surface protein A.

To date our studies demonstrate that PspA is a highly immunogenic molecule in mice and that it can elicit immunity to otherwise fatal infections following iv, ip, in, and it challenge. Although the molecule is serologically variable, it is sufficiently cross-reactive so that immunization with a single PspA can protect against strains of highly diverse serotypes. It is anticipated that a vaccine composed of a mixture of carefully chosen PspA molecules will be able to elicit protective immunity to virtually all pneumococci. If this vaccine proved efficacious in man, it would provide a more simple and less costly means of immunizing against pneumococcal infection than using recombinant vaccines. This could be especially important in the developing world where the cost of successful vaccines must be no more than pennies per dose. If PspA is found to be less efficacious than capsular polysaccharides, it may be valuable as a protein component of a PS-protein conjugate vaccine. In this capacity, PspA might expand the breath of protection elicited by a vaccine composed of only a few polysaccharide-protein conjugates representing capsule types most commonly associated with infectious pneumococci.

PspA, a protection-eliciting pneumococcal protein: immunogenicity of isolated native PspA in mice.

PspA is a surface exposed virulence factor of S. pneumoniae that can elicit protective immunity to pneumococcal sepsis in mice. It can be released from pneumococci by washing them with a solution containing 2% choline chloride, by growing pneumococci in media containing 1.2% choline chloride, or by growing pneumococci in media in which the choline has been replaced by ethanolamine. Our results indicate that PspA is the major protection-eliciting antigen in each of these preparations. Two injections of < or = 1 microgram of native PspA purified by use of a choline-Sepharose column are highly immunogenic in BALB/c and CBA/N mice, and even in the absence of adjuvant can elicit protection against otherwise fatal sepsis with 100 times the LD50 of S. pneumoniae. Fragments comprising the N-terminal 115 and 245 amino acids of PspA were able to elicit protection but only in the presence of complete Freund's adjuvant (CFA). In the absence of CFA the 245 amino acid fragment was less than 1/100 as immunogenic as native PspA.